Infrared Spectral Correlations for Crystalline and Amorphous trans- 1,4

Macromolecules 1988,21, 2075-2079

2075

Infrared Spectral Correlations for Crystalline and Amorphous trans-1,4-Polyisoprene E. Woodward*

Michal Gavish, Peter Brennan, a n d A r t h u r

Chemistry Department, The City College and The Graduate School, The City University of New York, New York, New York 10031. Received June 2, 1987 ABSTRACT: The infrared spectra for a- and P-trans-1,4-polyisopreneare compared, and a correlation is found between both the frequencies of their observed vibrational modes and their potential energy distribution from normal coordinate calculations for a single chain. Each band in the P spectrum corresponds to either one or two bands in the CY spectrum. Correlation between each of the spectra of the two crystalline forms and the amorphous TPI is used to assign the infrared bands of the latter. Introduction truns-1,4-Polyisoprene, TPI, precipitates from various solvents as single lamellas with crystalline cores and amorphous surfaces1i2 or as multilamellar structure^,^^^ depending on the crystallization conditions. Two crystal forms, a and @, have been clearly identified for this polymer. The a-form has a monoclinic unit cell with two chains, each containing two repeat units! The @-formhas an orthorhombic unit cell with four chains, each containing one repeat unit! Partially crystalline TPI can be prepared from solution with only the a-form, only the @-form,or both crystal forms present., The nature of the fold surface in solution-crystallized TPI lamellas has been investigated by using quantitative chemical reactions in suspension coupled with carbon-13 NMR analysis.'~~ It was believed of interest to explore the application of Fourier transform infrared spectroscopy to the characterization of the crystalline and noncrystalline components in solution-crystallized TPI. Use of the infrared method depends on assignment of the spectral bands, as obtained by normal-coordinate calculations. Single-chain normalcoordinate calculations for a- and @-TPIwere carried out previously by Petcavich and C01eman.~In that work assignments were given for the spectral bands for the @-form but only for a few of the bands for the a-form. In the present work, these calculations were repeated in order to obtain assignments for the latter. The force constant for the double bond was changed, and a unique force constant for the C-CH, bond was introduced. The geometry given for the a-form from X-ray analysis5 was adopted in the present work; this differs from that used in the earlier calculations in the C-C bond length, in some of the bond angles and in all of the dihedral angles. The new force constants were also used in the analysis of the TPI p crystalline form in order to compare the calculated frequencies and the potential energy distributions with those for the a-form. As the normal-coordinate analysis of TPI progressed, it was realized that a complete correlation existed between the observed infrared spectral frequencies for the two crystal forms. Each vibrational band in the spectrum for the p-form is correlated to a singlet in a few cases or to a doublet in the majority of cases in the spectrum of the a-form. The spectral frequency correlation for the two crystalline forms was also extended to the bands in the amorphous spectrum. The relatively broad infrared bands observed are expected. However, since the conformations characteristic of the two crystal forms are also highly probable ones for the amorphous chain, overlap of the amorphous and crystalline bands must occur. This overlap can be used as a means of assignment of the amorphous bands in terms 0024-9297/88/2221-2075$01.50/0

Table I Geometric Parameters of TPI C(4a)-[-C(l)-C(2)=C(3)-C(4)-] [C(1')-C(2')=C(3')-C(4')-l-c(1") C(5')

C(5)

bond length (A)

bond angle, $ (deg)

dihedral angle, 7 (deg)

a-TPI

j3-TPI C=C C-C C-H

1.33 1.54 1.09

$123 $234 $341,

HCH CCH C=CH

120 125 109.5 109.5 109.5 120

71234

'4a123 ~ 2 % ~ ' 7341,2,

180 117 -117 180

of the calculated assignment for the a- and @-crystalline structure. Experimental Section To obtain the @-crystallineform, we crystallized synthetic TPI from 1%(w/v) amyl acetate solution at 0 "C, followed by slow heating of the suspension liquid to 30 "C. This resulted in a morphology of curved stacks of overgrown lamellas with a semicrystalline ~tructure.~ The a-form was obtained by a precooling method of crystallization from 0.1% hexane solution that involves precipitation at 0 "C, redissolution at 32 O C , and crystallization at 20 "C. This resulted in semicrystalline lamellas with an ellipsoidal shape and pointed ends. Mats were formed by filtration of the above suspension onto Teflon filters. These were dried at room temperature. The Fourier transform infrared spectra were obtained from 450 to 4000 cm-' at 4 cm-' resolution by using a Digilab FTS 40 spectrometer. In order to obtain the amorphous spectrum, we placed one of the semicrystalline f i i s in a heating cell and recorded its infrared spectrum at 65 "C. At this temperature,all the sharp peaks that are associated with the crystalline structure disappear from the spectrum,leaving a spectrum that contains broad bands only. This amorphous spectrum was then subtracted from both semicrystalline a-and @-spectragiving 100% crystalline spectra with no detectable amount of the other crystalline form. Normal-coordinatecalculations were carried out for TPI single chains in each of the two stable crystalline forms by using a computer program written by Boerio.loJ1The molecular parameters of the a- and P-crystal structures were taken from earlier X-ray studies5"and are summarized in Table I. The F matrices for the CY and @ repeat conformational units were constructed by transferring to them unrefined force constantsfrom model compounds. Most of the force constants involving skeletal vibrations 0 1988 American Chemical Society

Macromolecules, Vol. 21, No. 7, 1988

2076 Gavish e t al.

force constant He

HO rl r2

7D FTw

KT KKb KD~ Kd Kt

H, H, Hs

H:

Table I1 Valence Force Constants for TPI" force force value constant value constant 0.910 H: 0.611 FKr' 0.944 HJ 0.540 F O B 0.344 H, 0.560 F8, 0.199 H+ 0.480 Fd 7T Fe+ 0.328 0.024 F,s 7Kb 0.0073 0.419 FDT FCf 4.384 0.094 4.672 FTR 0.122 fs; f@tt Fdd 0.004 7.901 Fmb 0.037 f.,., 4.947 f,,' FD, 4.524 0.355 F T ~ 0.341 f.,: 4.699 f,# FT+ 0.333 1.049 fwi FT., 0.066 0.664 0.668 FT, 0.075 f,,' 0.529 fw'

KT = KR

Fyv

Ha= H,q

TT

FTv FTJ.

= FOB

=

TR

=

Fu,

= Fw8

= FDc

FT+

= FD+

F,, = F~IL fs,'

fTVt= f+s fwu

= fee

fey'

value 0.174 -0.032 0.015 0.027 -0.029 -0.028 -0.031 0.010 -0.006 0.120 -0.02 0.008 0.029 0.080 -0.045 0.073

= f+v = fd

fS8 = fd = f w f,' = fd = f,IL

"The symbols for force constant definitions are taken from ref 15. The symbols for the internal coordinates for TPI are shown in Figure 1. All stretch force constants are in mdyn/A; stretch-bend interactions are mdyn/rad; bend constants are in units of (mdyn. A)/rad2. Most force constants are transferred from trans-l,4polybutadiene12 unless otherwise noted. Force constants transForce constants transferred ferred from trans- and ci~-butene.'~J~ from po1ypropylene.le

Table I11 Correlation of Observed and Calculated a- and B-TPI Infrared Frequencies P-TPI WTPI freq (cm-9 PED" freq (cm-') PED" obsd calcd (%) obsd calcd ("lo) 3022 3019 99K1 3018 3018, 3017 2979 2959 loOK, 2970 2965, 2965 2941 2963, 2963 2965 2957 100K, 2943 2921 100Kd 2918 2922, 2923 2879 2914, 2914 2914 2918 l00Kd 2872 2871, 2868 2906 2887 99K, 2851 2850, 2850 2855 2847 99Kd 2830 2842, 2841 2846 2841 99Kd 1664 1670 7 2 K ~l, 2 K ~ 1672 1669, 1670 1579 1559 1540 1523 1450 1463 93HF 1450 1469 71Hi, 18H.. 1463 91H; 1463, 1463 92H; 1462, 1462 92H, 1454 75H6 1460 75H6, llH7, 1lH.g 1430 1446 77H6 1430 1448 80H6, llH7, llH8 1446 80Hs. lOH,. 12Ha 1384 1387 39Hp40Ht 1383 1377 28H;i 32H;,' 18Hi 1373 41H,, 47Ht 1348 1361 10Hr, 12Ht, 1340 1347 38H,, 15H8,15H,, 17Kr 17Hg 38H,, bH8 1324 1335 61H7, i8H8, 1320 1306 11 f r r

1280 1322 45H-. 40Ha" I ,

1260 1252 44H,, 45Ha" I ,

I

997 1010 33&, 23Ht 978 992 50Ht, 1 6 K ~ 962

946 57Ht, 2 5 K ~

877

865 42r2, 2drD

800

816 5 5 K ~

750

742 51H,, 21H8

600

586 26H8, 14H,, 20K~

474

514 36r1, isTD

b

455 11Hp 40H,,

1048 1030 1018 992 995 994 965 964 963 882 886 862 872 800 816 780 810 750 770 730 750 618 625 555 490

573 505

470

490 18r1, 26H0, 20H,,

441

i7r1, i i ~3 ~ w w, , l0K~ 71Hp, 19H, 18Hp, 16H, 12H0, 26H,, 28H, 15H8, 22H,, 17Hu, l0K~ 20H,, 25H0, 1 6 7 ~ ~OKT, 25H8, 1 6 ~

373 67H8, 1 2 K ~

351

225 40H,, 3 1 H ~

248 233

174 21r1,62H,

176 150 106 91 86 81

316

1500

1000

500

FREQUENCY (CM-')

Figure 2. Infrared spectra of T P I in the 450-1700 and 2500-3100 cm-' regions: (A) amorphous TPI; (B)@-TPI;( C ) a-TPI. as well as the different methylene modes were transferred from truns-polybutadiene.'* The force constants of the methyl group as well as those involving the double bond were transferred from trans- and cis-butene.13J4 The set of force constants, as shown in Table 11, was applied to both the a- and @-structures.

119 3178 90 4078,2 3 7 ~ 85 9 5 7 ~

60H;;. 1 9 K ~ 56Hc, 17Kr

450

l%T

0 -0

42H.,. 51Ho

1212 1192 21H,, 24H.g, ~OKT,18H, 1150 1133 27H,, 39HO 1150 1166 1107 1093 6OKm 1OHa 1105 1089 1099 1083 1058 1039 21&, 25Ht 1050 1051 . I

Figure 1. Internal coordinates of T P I repeat monomer unit.

1280 1262 1256 1260 1248 1244 1250 1235 1230 1205 1197

1 KT

2W,, 4 2 7 ~

4678 957K 96sK

a Contributions to potential energy distribution of >lo%. Spectra not observed below 450 cm-' in this work.

Results and Discussion The infrared spectra for a m o r p h o u s TPI, 100% 6 , and 100% a a r e given i n Figure 2 (A, B, and C , respectively)

Macromolecules, Vol. 21, No. 7, 1988 Table IV Correlation of the Observed Crystalline and Amorphous Infrared Frequenciesa fl-TPI amorphous a-TPI obsd TPI obsd obsd type of freq (cm-') freq (cm-') freq (cm-') vibration 3015 (sh) 3018 (sh) w.(=CH) 3022 (sh) 2970 ( 8 ) 2979 (sh) 2975 (sh) 2941 (vs) 2961 (9) 2965 (vs) 2925 (vs) 2918 (vs) 2943 (vs) 2879 (vs) 2914 (vs) 2920 (vs) 2872 (vs) 2912 (vs) 2906 (vs) 2851 (s) 2855 (s) 2848 (s) 2830 (s) 2846 ( 8 ) 1672 (m) 1664 (m) 1665 (m) 1579 (w) 1570 (vw) 1540 (w) 1540 (vw) 1450 ( 8 ) 1450 ( 8 ) 1450 (s) 1430 (sh) 1430 (sh) 1430 (sh) 1383 (s) 1384 ( 8 ) 1383 (s) 1360 (m) 1340 (m) 1348 (m) 1329 (m) 1324 (w) 1280 (w) 1260 (m) 1212 (m)

1150 (m) 1107 (m) 1058 (vw) 997 (m) 978 (w) 962 (m) 877 (s) 800

(8)

750 (m-s) 600 (ms) 474

(9)

1307 (sh) 1281 (w) 1253 (w-br)

1320 (w) 1280 (w) 1260 (w) 1250 (w)

1220 (w) 1205 (w) 1150 (m)

1205 (m)

1099 (m-s, br) 1033 (m) 987 (m) 976 (m) 924 (w) 884 (sh) 860 (sh) 842 (s) 800 (sh) 764 743 595 570 520